US2454959A - Optical apparatus for showing rotating parts at rest - Google Patents

Optical apparatus for showing rotating parts at rest Download PDF

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US2454959A
US2454959A US648428A US64842846A US2454959A US 2454959 A US2454959 A US 2454959A US 648428 A US648428 A US 648428A US 64842846 A US64842846 A US 64842846A US 2454959 A US2454959 A US 2454959A
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prism
speed
mirror
axis
rotating
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Norman F Barnes
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General Electric Co
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01PMEASURING LINEAR OR ANGULAR SPEED, ACCELERATION, DECELERATION, OR SHOCK; INDICATING PRESENCE, ABSENCE, OR DIRECTION, OF MOVEMENT
    • G01P3/00Measuring linear or angular speed; Measuring differences of linear or angular speeds
    • G01P3/36Devices characterised by the use of optical means, e.g. using infrared, visible, or ultraviolet light
    • G01P3/40Devices characterised by the use of optical means, e.g. using infrared, visible, or ultraviolet light using stroboscopic means
    • DTEXTILES; PAPER
    • D06TREATMENT OF TEXTILES OR THE LIKE; LAUNDERING; FLEXIBLE MATERIALS NOT OTHERWISE PROVIDED FOR
    • D06HMARKING, INSPECTING, SEAMING OR SEVERING TEXTILE MATERIALS
    • D06H3/00Inspecting textile materials
    • D06H3/02Inspecting textile materials visually
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02PCONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
    • H02P5/00Arrangements specially adapted for regulating or controlling the speed or torque of two or more electric motors
    • H02P5/46Arrangements specially adapted for regulating or controlling the speed or torque of two or more electric motors for speed regulation of two or more dynamo-electric motors in relation to one another
    • H02P5/52Arrangements specially adapted for regulating or controlling the speed or torque of two or more electric motors for speed regulation of two or more dynamo-electric motors in relation to one another additionally providing control of relative angular displacement

Definitions

  • My invention relates to apparatus for the continuous visual inspection of rotating apparatus.
  • Figs. 1 and 2 show an object as observed through a Dove prism when the prism is rotated on'its axis'through an angle of 180 degrees.
  • Fig. 3 represents a simplified embodiment of my invention
  • Fig. 4 represents a preferredform of prism rotating and mirror angle adjusting apparatus embodying my invention
  • Fig. 5 is a simplified wiring diagram for the- .speed control of the rotating prism such as is shown in Fig.4:
  • Fig. 6 represents a preferred form of such speed control employing electronic current controlf
  • Fig. 7 represents another form of image revolving prism; and
  • Fig. 8 represents a tachometer embodying my invention.
  • Fig. 1 at i, I have represented an optical prism of a form which is sometimes called a Dove prism. If an object 2 be observed through the longitudinal axis of the prism as representedin Fig. 1, such object will appear as inverted. Thus, if the observer's eye be placed at point 3 looking'towards 2 through the prism, the object will appear inverted as drawn at point 3. The reason forthis is seen from tracing light rays 4, 5.- and 6 from the top, middle, and bottom of the object through the prism to the point of observation at 3.
  • the horizontal light rays are bent downward as they enter the right-hand end of the prism, are reflected upward by the broad surface I of the prism, and then bent downward to the horizontal as they leave the left end of the prism. Due to the shape and dimensions of the prism, the upper ray 4 travels farther in a downward direction in the prism than in the upward direction, and hence, appears lower down as it leaves the prism; while the lower beam 6 travels farther in an upward than in a downward direction in the prism. and hence, appears higher up as it leaves the prism.
  • the center beam 5 travels the same distance up and down in the prism, and hence, emerges on the some horizontal level as it entered. Hence, the object as thus observed through the axis of the prism in Fig. 1 appears inverted, but otherwise in its true perspective as to size and shape, and alignment with the center line which is the horizontal line of beam 5.
  • Fig. 2 shows the prismi as having been rotated on its central horizontal axis. corresponding to the axis of the central horizontal ray 5, 180 degrees from the position of Fig.1 While the upper and lower rays 4 and 6 take quite different paths through the prism, the observed image is exactly the same as in Fig. 1, and is inverted but other- 1 Claim. (CL 88-14) wise in its true perspective as to size, shape, and
  • the prism may have-a square cross section and will then have a length to-thickness ratio (the length being measured at the center) of nearly 4 to 1, and will have equal angles between the end surfaces and the internal reflecting side i. the value of such angles depending upon the index of refraction of the material used.
  • Such a prism has the property of producing a rotation of light beams passing through it when the prism itself is rotated about its long axis. This optical rotation occurs at a speed exactly twice that speed at which the prism is mechanically rotated. If the object 2, Fig. 1, be rotated about the center axis beam 5, and the prism I be rotated in the same direction about the same axis at half the speed of the object, a counter-rotation of the image of the rotating object will occur and it will appear at point 3 as if standing still.
  • Fig. '7 shows another form of image revolving prism capable of producing this image inversion and counter-rotation of the image.
  • the prism is preferably made of flint glass and has its internal reflecting surface 8 silvered.
  • the three prism angles are each 60 degrees. Either form of prism may be used in my invention.
  • Fig. 3 I have shown a simple form of apparatus embodying my invention, adapted for ohscrving a certain part 9 of a rotating object Iii.
  • the object Hi may, for example, be the propeller wing of an Autogiro, and the part 9 one of its tips. and the purpose of the arrangement being to observe the nature and extent of bending or vibrational the part 9 at various speeds of the propeller.
  • On the axis of rotation of the propeller is a mirror i I set at an angle to reflect the surface at 9 along the axis of rotation. This mirror is driven at the same speed and in the 3 same direction as propeller It so as always to reflect the same spot 2 at all rotatlve positions of the propeller.
  • the mirror is mounted on a shaft extension 12 of the propeller and is thus driven with it.
  • This arrangement has the effect of bending the axis of revolution of turned about its pivot 33 to some such position as indicated in dotted lines, this movement being resisted by the tensioningo'f spring 35.
  • the adjusted position of collar section 40 and mirror 28 is determined by the adjusted position of an outer collar section 43 which does not rotate the light rays such that the center ofspot 3 lies on such axis with the spot revolving about such center when the object I is revolved.
  • the rotating object of which a stationary image is produced is the spot at 8 of appreciable area.
  • Dove rism I mounted for rotation and driven from shaft extension l2 at one-half the speed of propeller l0, and in the same'direction through gears l2, l4, l5, and iii.
  • a mirror ll may be used to reflect the image at any desired observation angle from the axis of rotation.
  • a condensing lens I8 is preferably used to assist in focusing the image rays to the position with tubular part 22 but which is lidably adjustable in an axial direction within stationary housing 30. There is a ball bearing connection of the observer's eye at l8. As thus arranged, the
  • part of surface at 3 on the propeller may be continuously observed as if the propeller were stationary while the propeller is rotating at any and all speeds.
  • the image will of course show any bonding or vibration of the surface at 8 but the apparatus will cancel out the rotary movement of the propeller blade about its axis of rotation.
  • the angle of the mirror I I may be changed to observe diiferent parts of the periphery of the propeller It! Or parts nearer its axis of rotation.
  • the apparatus diifers from a stroboscope in that the point under observation is observed continuously and not intermittently as with a stroboscope. Also, changes in the speed of rotation of the'ob- J'ect under observation have no eifect upon the proper functioning of the apparatus. It is equally effective at any speed from zero upward without adjustment.
  • a preferred form of apparatus which is mechanically independent of the rotating part under observation is shown partially in section in Fig. 4.
  • a Dove prism l is adiustably mounted in a tubular holder 20.
  • Holder 28 is mounted for rotation on its axis and the longitudinal axis of the prism 20 by means of ball bearings 2
  • the tubular supporting member 22 is also rotatively mounted on the same axis as the prism l and carries a reflecting mirror 28 serving the purpose of mirror ll, Fig. 3.
  • Tubular support 22 is rotatively mounted by ball bearings 23 in a stationary housing 30 and is driven in the same direction and at twice the speed of prism I from motor 21 through gears3l,32, 25, and 25.
  • the mirror 28 is hinged at "'33 between a pair of lugs 34, only one of which is shown in the sectional view, Fig. 4: and the mirror is biased about its pivot 33 to the inactive position shown in full lines in Fig. 4 by a spring 35 fastened between a lever arm 36 extending from the back of the mirror near its pivot and a crosspin 31 extending between a pair of lugs 38, only one of which is shown, and which are on a collar 29 which is secured about the right end of tubular support 22. Lugs 34 are also supported from collar 38.
  • a collar section 48 Rotatable with tubular part 22 but slidable endwise thereon is a collar section 48 having a lug 4
  • the endwise movement of these mirror angle adjusting parts is controlled by three bolts 44 threaded through lugs 43' in collar section 43 and rotatively supported in bearings 45 on i the exterior of housing 80.
  • One of these bolts may be turned by a rod 48 connected with the bolt through a universal joint 41.
  • the other bolts 44 not shown are turned with the one shown through gearing, part of which is shown at 48 and 49.
  • the mirror angle may be changed while the mirror is'rotating at double the speed of the prism l.
  • the electrical control of the speed of the driving motor 21 of Fig. 4 is somewhat schematically illustrated in Fig 5.
  • the speed of motor 21 is measured by a synchronous rotary motion Selsyn device 58.
  • the speed of the object In under investigation is measured by a similar Selsyn device 5
  • a more-refined speed control is desirable and in addition, rotary control of mirror 28 about the axis of rotation of prism i while the apparatus is in operation.
  • This is provided for in the control of Fig. 6.
  • 50 and 5i represent the Selsyn devices for measuring the speeds of the motor 21 and the object l8 under observation.
  • the differential Selsyn has both of its alternating current windings 55 and 56 normally stationary, although one winding 55 is supported so that it can be manually rotatively adjusted relative to winding 56 by a hand wheel 51.
  • the power supply for the series direct current reversible motor 21 which drives the mirror 28 and prism l of Fig.4 is through a phase sensitive electronic control apparatus 58.
  • Both .the Selsyn system and the phase sensitive electronic control apparatus are supplied from the same source of alternating current 53, and the electronic control apparatus is electrically connected to the single phase winding of the Selsyn device 50 in a way to be sensitive to the direction and amount of phase shift between the source ofsupply 59 and any signal coming to it from Selsyn 50.
  • the entire surface of object which faces toward the prism I can be examined by the use of the apparatus while such object is rotating at any speed and, of course, also when standing still.
  • the speed at which objeot I0 is rotating at any time can of course be measured by measuring the speed of the rotating, prism l with a tachometer and multiplying the reading by '2.
  • Fig. 8 shows a simple tachometer embodying the principle of the invention. At 60 is represented the end of a high speed shaft having a distinctive mark on one radius so as to be readily observed.
  • a pair of rotatively mounted prism holders BI and 62 having prisms therein of the form shown in Fig. 7.
  • an electric motor geared to the two prism hold- .ers so as to drive them in opposite directions at the same speed, which speed is adjustable by means of a variable resistance 64 in the motor. supply circuit.
  • the motor also is connected to op erate a conventional tachometer 65 of any suitable type.
  • Apparatus for continucuslyproducing a stationary image of a revolving object comprising apparatus having an image revolving prism mounted for rotation on itsimagerevolving axis,
  • a mirror for reflectingan image of anobject at one side of said axisxalongsaidfaiiis so that they '1 same may be observed 'thi'oughthe prismga-moe tor for revolving both-the prism and-the mirror on said axis, with theymirror revolving at twice the speed of the 'jprism', a. i s'ynchronous .motion transmitting system. including 'a device driven by'said motor and a Selsyn device adapted to be driven'by the rotating object, and a difierenti-al Selsyn deviceelectricallyconnected in said system betweenthe first-two mentioned Selsyn devices, sp ed control means.
  • said speed control means including a phase angle responsive electronic controller for said motor which controller is-respcnsive to changes in phase relation detected by said synchronous motion transmitting system when said speed relation departs from said predetermined relation, said differential Selsyn having a pair of relatively rotatable normally stationary windings through which the motion transmitting system is inductively coupled, and means for adjusting the relative rotary positions of said windings for the purpose of shifting the angular rotative relation between said mirror and rotating ob- J'ect.

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Physics & Mathematics (AREA)
  • Chemical & Material Sciences (AREA)
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Description

N. F. BARNES Nov. 1948.
I OPTICAL APPARASTHS FOR SHOWING ROTATING PARTS AT REST Filed Feb. 18,1946
T 2 Sheets-Sheet '1 invent or; Norm ah FBarn es, by WWI/Q Hls Attorn ey.
Nov. 30, 1948. N. F. BARNES BEI CAL APPARATUS FOR SHOWING ROTATING PARTS AT REST 2 Shets-Shqet 2- Figs.
Filed Feb. 18. 1346 In verwkor Norm arw F. Barnes,
His Attormey.
Patented N... so, 1948 OPTICAL APPARATUS FOR SHOWING ROTAT NG PARTS AT REST Norman F. Barnes, Schenectady, N. Y., assigncito General Electric Company, a corporation of New York Application February 18, 19 46, Serial No. 648,428
. 1 My invention relates to apparatus for the continuous visual inspection of rotating apparatus.
The features of my invention which are believed to'be novel and patentable will be pointed out in the claim appended hereto. For a better understanding of my invention, reference is made in the following description to the accompanying drawings in which Figs. 1 and 2 show an object as observed through a Dove prism when the prism is rotated on'its axis'through an angle of 180 degrees. illustrating a basic principle employed in my apparatus: Fig. 3 represents a simplified embodiment of my invention; Fig. 4 represents a preferredform of prism rotating and mirror angle adjusting apparatus embodying my invention: Fig. 5 is a simplified wiring diagram for the- .speed control of the rotating prism such as is shown in Fig.4: Fig. 6 represents a preferred form of such speed control employing electronic current controlf Fig. 7 represents another form of image revolving prism; and Fig. 8 represents a tachometer embodying my invention.
Referring now to Fig. 1, at i, I have represented an optical prism of a form which is sometimes called a Dove prism. If an object 2 be observed through the longitudinal axis of the prism as representedin Fig. 1, such object will appear as inverted. Thus, if the observer's eye be placed at point 3 looking'towards 2 through the prism, the object will appear inverted as drawn at point 3. The reason forthis is seen from tracing light rays 4, 5.- and 6 from the top, middle, and bottom of the object through the prism to the point of observation at 3. The horizontal light rays are bent downward as they enter the right-hand end of the prism, are reflected upward by the broad surface I of the prism, and then bent downward to the horizontal as they leave the left end of the prism. Due to the shape and dimensions of the prism, the upper ray 4 travels farther in a downward direction in the prism than in the upward direction, and hence, appears lower down as it leaves the prism; while the lower beam 6 travels farther in an upward than in a downward direction in the prism. and hence, appears higher up as it leaves the prism. The center beam 5 travels the same distance up and down in the prism, and hence, emerges on the some horizontal level as it entered. Hence, the object as thus observed through the axis of the prism in Fig. 1 appears inverted, but otherwise in its true perspective as to size and shape, and alignment with the center line which is the horizontal line of beam 5.
Fig. 2 shows the prismi as having been rotated on its central horizontal axis. corresponding to the axis of the central horizontal ray 5, 180 degrees from the position of Fig.1 While the upper and lower rays 4 and 6 take quite different paths through the prism, the observed image is exactly the same as in Fig. 1, and is inverted but other- 1 Claim. (CL 88-14) wise in its true perspective as to size, shape, and
alignment. If the object 2 is observed-through the prism on the axis of revolution during such l-degree rotation of the prism. the image would appear to have made a complete revolution in a direction opposite to that in which the prism is turned. Furthermore, the image is always in true perspective of the object observed except as to orientation about the axis of revolution. For the purpose of this application prisms which are capable of this opticaliphenomenon are called image revolving prisms, and the axis about which the prism is revolved and through which the phenomenon is observed is called the image revolving axis. It. will be evident that this optical phenomenon requires a certain length of the prism in relation 'tothe distance of the reflecting surface I from the axis of rotation of the prism for a given coeflicient of refraction and surface angles at the prism ends. The prism may have-a square cross section and will then have a length to-thickness ratio (the length being measured at the center) of nearly 4 to 1, and will have equal angles between the end surfaces and the internal reflecting side i. the value of such angles depending upon the index of refraction of the material used. For a discussionof the design of Dove prisms, see page 158 of Fundamentals of Optical Engineering by Jacobs; McGraw-Hill Book Co.. 1943. Such a prism, called a Dove prism, has the property of producing a rotation of light beams passing through it when the prism itself is rotated about its long axis. This optical rotation occurs at a speed exactly twice that speed at which the prism is mechanically rotated. If the object 2, Fig. 1, be rotated about the center axis beam 5, and the prism I be rotated in the same direction about the same axis at half the speed of the object, a counter-rotation of the image of the rotating object will occur and it will appear at point 3 as if standing still.
Fig. '7 shows another form of image revolving prism capable of producing this image inversion and counter-rotation of the image. Here the prism is preferably made of flint glass and has its internal reflecting surface 8 silvered. The three prism angles are each 60 degrees. Either form of prism may be used in my invention.
In Fig. 3. I have shown a simple form of apparatus embodying my invention, adapted for ohscrving a certain part 9 of a rotating object Iii. The object Hi may, for example, be the propeller wing of an Autogiro, and the part 9 one of its tips. and the purpose of the arrangement being to observe the nature and extent of bending or vibrational the part 9 at various speeds of the propeller. On the axis of rotation of the propeller is a mirror i I set at an angle to reflect the surface at 9 along the axis of rotation. This mirror is driven at the same speed and in the 3 same direction as propeller It so as always to reflect the same spot 2 at all rotatlve positions of the propeller. As-represented, the mirror is mounted on a shaft extension 12 of the propeller and is thus driven with it. This arrangement has the effect of bending the axis of revolution of turned about its pivot 33 to some such position as indicated in dotted lines, this movement being resisted by the tensioningo'f spring 35. The adjusted position of collar section 40 and mirror 28 is determined by the adjusted position of an outer collar section 43 which does not rotate the light rays such that the center ofspot 3 lies on such axis with the spot revolving about such center when the object I is revolved. Here the rotating object of which a stationary image is produced is the spot at 8 of appreciable area. Also on the axis of rotation is a Dove rism I mounted for rotation and driven from shaft extension l2 at one-half the speed of propeller l0, and in the same'direction through gears l2, l4, l5, and iii. For convenience of the observer, a mirror ll may be used to reflect the image at any desired observation angle from the axis of rotation. A condensing lens I8 is preferably used to assist in focusing the image rays to the position with tubular part 22 but which is lidably adjustable in an axial direction within stationary housing 30. There is a ball bearing connection of the observer's eye at l8. As thus arranged, the
part of surface at 3 on the propeller may be continuously observed as if the propeller were stationary while the propeller is rotating at any and all speeds. The image will of course show any bonding or vibration of the surface at 8 but the apparatus will cancel out the rotary movement of the propeller blade about its axis of rotation. The angle of the mirror I I may be changed to observe diiferent parts of the periphery of the propeller It! Or parts nearer its axis of rotation. The apparatus diifers from a stroboscope in that the point under observation is observed continuously and not intermittently as with a stroboscope. Also, changes in the speed of rotation of the'ob- J'ect under observation have no eifect upon the proper functioning of the apparatus. It is equally effective at any speed from zero upward without adjustment.
A preferred form of apparatus which is mechanically independent of the rotating part under observation is shown partially in section in Fig. 4. A Dove prism l is adiustably mounted in a tubular holder 20. Holder 28 is mounted for rotation on its axis and the longitudinal axis of the prism 20 by means of ball bearings 2| in a second tubular supporting member 22, and may be driven through gears 23, 24,- 25. and 28 by an adjustable speed electric motor 21. The tubular supporting member 22 is also rotatively mounted on the same axis as the prism l and carries a reflecting mirror 28 serving the purpose of mirror ll, Fig. 3. Tubular support 22 is rotatively mounted by ball bearings 23 in a stationary housing 30 and is driven in the same direction and at twice the speed of prism I from motor 21 through gears3l,32, 25, and 25.
The mirror 28 is hinged at "'33 between a pair of lugs 34, only one of which is shown in the sectional view, Fig. 4: and the mirror is biased about its pivot 33 to the inactive position shown in full lines in Fig. 4 by a spring 35 fastened between a lever arm 36 extending from the back of the mirror near its pivot and a crosspin 31 extending between a pair of lugs 38, only one of which is shown, and which are on a collar 29 which is secured about the right end of tubular support 22. Lugs 34 are also supported from collar 38. Rotatable with tubular part 22 but slidable endwise thereon is a collar section 48 having a lug 4| extending from its right-hand end on the side or the axis of rotation of the prism on which the mirror 28 is pivoted. Between lug 4| and lugs 36 there is a link connection 42 so thatby sliding collar section 40 to the right, the mirror may be between collar sections 40 and 43 so that they both participate in the same endwise sliding action, although part 40 rotates and part 43 does not. The endwise movement of these mirror angle adjusting parts is controlled by three bolts 44 threaded through lugs 43' in collar section 43 and rotatively supported in bearings 45 on i the exterior of housing 80. One of these bolts may be turned by a rod 48 connected with the bolt through a universal joint 41. The other bolts 44 not shown are turned with the one shown through gearing, part of which is shown at 48 and 49. Thus, by turning rod 45, the mirror angle may be changed while the mirror is'rotating at double the speed of the prism l.
The electrical control of the speed of the driving motor 21 of Fig. 4 is somewhat schematically illustrated in Fig 5. The speed of motor 21 is measured by a synchronous rotary motion Selsyn device 58. the speed of the object In under investigation is measured by a similar Selsyn device 5|, and these speeds. are compared by a differential Selsyn device 52 having stationary and rotary parts electrically connected with Selsyn devices 5| and 50, respectively. If the speed of motor 21 is correct or such as to drive mirror 28 at the same speed and prism l at half speed of object It]. there is no rotary movement of the rotary part of the differential Selsyn 52. However, if motor 21 is fast, Selsyn 52 will rotate in one direction and if slow, in the opposite direction; and such rotary movement may be used to control the speed of motor 21 so as to keep it correct. To this end rotary movement of differential Selsyn 52 is arranged to adjust a rheostat 53 in the supply circuit 54 of motor 21.
Generally a more-refined speed control is desirable and in addition, rotary control of mirror 28 about the axis of rotation of prism i while the apparatus is in operation. This is provided for in the control of Fig. 6. As in Fig. 5, 50 and 5i represent the Selsyn devices for measuring the speeds of the motor 21 and the object l8 under observation. The differential Selsyn has both of its alternating current windings 55 and 56 normally stationary, although one winding 55 is supported so that it can be manually rotatively adjusted relative to winding 56 by a hand wheel 51. The power supply for the series direct current reversible motor 21 which drives the mirror 28 and prism l of Fig.4 is through a phase sensitive electronic control apparatus 58. Both .the Selsyn system and the phase sensitive electronic control apparatus are supplied from the same source of alternating current 53, and the electronic control apparatus is electrically connected to the single phase winding of the Selsyn device 50 in a way to be sensitive to the direction and amount of phase shift between the source ofsupply 59 and any signal coming to it from Selsyn 50. When motor 21 is rotating the prism l and mirror 28 at the correct speeds to observe the object [0 as stationary, no signal comes to the electronic control apparatus 58 through theSelsyn system, and under such conditions the controller 58 is adjusted tosupply motor 21 with the proper amount of relation relative to source 59 which depends upon the direction of the departure from correct speed relation, and of a magnitude proportional to such departure, which signal will immediately change the power input to motor 21 to reestablish the correct speed relation. Such apparatus will cause the motor 21 to follow the speed changes, includlog starting, stopping, and reversing of object l0, precisely. During such operation the mirror 28, Fig. 4, may be swung from the full line position shown to a position such as is shown in dotted lines by turning rod 46, so that any part of the ro tating object from its axisof rotation to its periphery along a given radial line can be observed in detail while it is rotating at high speed.
If, now, it is desired to examine some portion of the rotating object on a different radial line, the adjustable winding 55 of the differential Selsyn is rotated relative to winding 56. This results in a shift in phase relation between these windings.
and a resulting signal to the thermionic regulat-' ing apparatus which will cause the motor 21 temporarily to speed up or slow down relative to object l until the signal disappears and the mirror 28 has been rotatively shifted on object ID by a corresponding amount. Thus, the entire surface of object which faces toward the prism I can be examined by the use of the apparatus while such object is rotating at any speed and, of course, also when standing still. The speed at which objeot I0 is rotating at any time can of course be measured by measuring the speed of the rotating, prism l with a tachometer and multiplying the reading by '2.
Fig. 8 shows a simple tachometer embodying the principle of the invention. At 60 is represented the end of a high speed shaft having a distinctive mark on one radius so as to be readily observed.
In line with the end of the shaft is a pair of rotatively mounted prism holders BI and 62 having prisms therein of the form shown in Fig. 7. At 63 is an electric motor geared to the two prism hold- .ers so as to drive them in opposite directions at the same speed, which speed is adjustable by means of a variable resistance 64 in the motor. supply circuit. The motor also is connected to op erate a conventional tachometer 65 of any suitable type.
When the shaft 60 is rotating and with the two prisms rotating at one-fourth the speed of the shaft, prism holder 6 l rotating in the same direction and prism holder 62 rotating in the opposite direction to the shaft, the image of the end of the shaft will appear to stand still when viewed through the tow prisms. To measure the speed of shaft 60, the speed of motor 63 is adjusted until the stationary image appears and then the speed is read on tachometer 65. If a 1-to-1 gear ratio is used between the motor and prism holders, the
. 6 tem must be driven in opposite directions but all should be driven at the same speed.
While the image which is observed with the apparatus described is in its true perspective if reasonable care is obtained in selecting mirrors and prisms and their proper alignment, the resulting image is inverted. In any case where an inverted image is objectionable, it can be reinverted by known optical means.
' In accordance with the provisions of the patent statutes I have described the principle of operation of my invention, together with the apparatus which I now consider to represent the best embodiment thereof, but I desire to have it understood that the apparatus shown is only illustrative and that the invention may be carried out by other means.
What I claim as new and desire to secure by Letters Patent of the United States is:
Apparatus for continucuslyproducing a stationary image of a revolving object comprising apparatus having an image revolving prism mounted for rotation on itsimagerevolving axis,
a mirror for reflectingan image of anobject at one side of said axisxalongsaidfaiiis so that they '1 same may be observed 'thi'oughthe prismga-moe tor for revolving both-the prism and-the mirror on said axis, with theymirror revolving at twice the speed of the 'jprism', a. i s'ynchronous .motion transmitting system. including 'a device driven by'said motor and a Selsyn device adapted to be driven'by the rotating object, and a difierenti-al Selsyn deviceelectricallyconnected in said system betweenthe first-two mentioned Selsyn devices, sp ed control means. for said motor for obtaining a predetermined speed relation between said mirror, prism and rotating object such that the image of the rotating object as reflected by said mirror and observed through said prism will appear stationary, said speed control means including a phase angle responsive electronic controller for said motor which controller is-respcnsive to changes in phase relation detected by said synchronous motion transmitting system when said speed relation departs from said predetermined relation, said differential Selsyn having a pair of relatively rotatable normally stationary windings through which the motion transmitting system is inductively coupled, and means for adjusting the relative rotary positions of said windings for the purpose of shifting the angular rotative relation between said mirror and rotating ob- J'ect.
NORMAN F. BARNES.
REFERENCES CITED The followingireferences are of record in the file of this patent:
UNITED STATES PATENTS Number Name Date 1,735,100 Wohlrabe Nov. 12, 1929 2,280,492 Kenngott Apr. 21, 1942 2,405,731 Beggs et al Aug. 13, 1946 FOREIGN PATENTS Number Country Date 263,797 Germany Sept. 11, 1913 703,362 Germany Mar. 7, 1941 67,372 Sweden May 14, 1929 OTHER REFERENCES Scientific American for July 1925, page 55.
US648428A 1946-02-18 1946-02-18 Optical apparatus for showing rotating parts at rest Expired - Lifetime US2454959A (en)

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Cited By (18)

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US2686453A (en) * 1950-08-01 1954-08-17 Nat Lab Mfg Corp Means for checking superposed impressions on a moving web
US2928952A (en) * 1958-08-20 1960-03-15 Curtis Lab Inc Optical scanning system
US2928489A (en) * 1955-04-13 1960-03-15 Texas Instruments Inc Seismic record viewer
US3077816A (en) * 1959-02-05 1963-02-19 Hirsch Max Three dimensional optical display apparatus
US3113485A (en) * 1961-06-21 1963-12-10 Dietrich Cornelius Frank Optical projection pantometers
DE1222576B (en) * 1954-06-01 1966-08-11 Nat Lab Mfg Corp Observation device for patterns printed on running tracks
US3449035A (en) * 1965-06-01 1969-06-10 James J Denaro Stroboscope mirror device
US3471236A (en) * 1964-03-30 1969-10-07 Us Army Prism for optical stroboscope
US3797908A (en) * 1970-03-11 1974-03-19 Atomic Energy Authority Uk Optical arrangements and apparatus
US3910690A (en) * 1972-02-02 1975-10-07 Wilkinson Sword Ltd Method and apparatus for determining visual acuity in a human subject
FR2462938A1 (en) * 1979-08-14 1981-02-20 Erno Raumfahrttechnik Gmbh LABORATORY CENTRIFUGE
US4403860A (en) * 1980-03-27 1983-09-13 Diffracto Ltd. Apparatus for determining dimensions
US4501950A (en) * 1982-09-07 1985-02-26 Caterpillar Tractor Co. Adaptive welding system
WO1987003677A1 (en) * 1985-12-05 1987-06-18 Baxter Travenol Laboratories, Inc. Optical data collection apparatus and method
US5825017A (en) * 1980-03-27 1998-10-20 Sensor Adaptive Machines Inc. Method and apparatus for determining dimensions
US5871391A (en) * 1980-03-27 1999-02-16 Sensor Adaptive Machine Inc. Apparatus for determining dimensions
US5940302A (en) * 1981-02-27 1999-08-17 Great Lakes Intellectual Property Controlled machining of combustion chambers, gears and other surfaces
US6138055A (en) * 1981-02-27 2000-10-24 Lmi Technologies Inc. Controlled machining of combustion chambers, gears and other surfaces

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US1735100A (en) * 1927-07-05 1929-11-12 Vogtlandische Maschinenfabrik Web-registering means
DE703362C (en) * 1938-07-15 1941-03-07 Aeg Device for observing rotating bodies with the help of optical erecting prisms
US2280492A (en) * 1940-04-23 1942-04-21 Ford Instr Co Inc Apparatus for testing transmission systems
US2405731A (en) * 1943-12-17 1946-08-13 Eastman Kodak Co Variable circle for stadiametric range finders

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US1735100A (en) * 1927-07-05 1929-11-12 Vogtlandische Maschinenfabrik Web-registering means
DE703362C (en) * 1938-07-15 1941-03-07 Aeg Device for observing rotating bodies with the help of optical erecting prisms
US2280492A (en) * 1940-04-23 1942-04-21 Ford Instr Co Inc Apparatus for testing transmission systems
US2405731A (en) * 1943-12-17 1946-08-13 Eastman Kodak Co Variable circle for stadiametric range finders

Cited By (22)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2686453A (en) * 1950-08-01 1954-08-17 Nat Lab Mfg Corp Means for checking superposed impressions on a moving web
DE1222576B (en) * 1954-06-01 1966-08-11 Nat Lab Mfg Corp Observation device for patterns printed on running tracks
US2928489A (en) * 1955-04-13 1960-03-15 Texas Instruments Inc Seismic record viewer
US2928952A (en) * 1958-08-20 1960-03-15 Curtis Lab Inc Optical scanning system
US3077816A (en) * 1959-02-05 1963-02-19 Hirsch Max Three dimensional optical display apparatus
US3113485A (en) * 1961-06-21 1963-12-10 Dietrich Cornelius Frank Optical projection pantometers
US3471236A (en) * 1964-03-30 1969-10-07 Us Army Prism for optical stroboscope
US3449035A (en) * 1965-06-01 1969-06-10 James J Denaro Stroboscope mirror device
US3797908A (en) * 1970-03-11 1974-03-19 Atomic Energy Authority Uk Optical arrangements and apparatus
US3910690A (en) * 1972-02-02 1975-10-07 Wilkinson Sword Ltd Method and apparatus for determining visual acuity in a human subject
FR2462938A1 (en) * 1979-08-14 1981-02-20 Erno Raumfahrttechnik Gmbh LABORATORY CENTRIFUGE
US4332349A (en) * 1979-08-14 1982-06-01 Erno Raumfahrttechnick Gmbh Centrifuge
US4403860A (en) * 1980-03-27 1983-09-13 Diffracto Ltd. Apparatus for determining dimensions
US5825017A (en) * 1980-03-27 1998-10-20 Sensor Adaptive Machines Inc. Method and apparatus for determining dimensions
US5871391A (en) * 1980-03-27 1999-02-16 Sensor Adaptive Machine Inc. Apparatus for determining dimensions
US5940302A (en) * 1981-02-27 1999-08-17 Great Lakes Intellectual Property Controlled machining of combustion chambers, gears and other surfaces
US6138055A (en) * 1981-02-27 2000-10-24 Lmi Technologies Inc. Controlled machining of combustion chambers, gears and other surfaces
US4501950A (en) * 1982-09-07 1985-02-26 Caterpillar Tractor Co. Adaptive welding system
WO1987003677A1 (en) * 1985-12-05 1987-06-18 Baxter Travenol Laboratories, Inc. Optical data collection apparatus and method
US4724317A (en) * 1985-12-05 1988-02-09 Baxter Travenol Laboratories, Inc. Optical data collection apparatus and method used with moving members
EP0377481A2 (en) * 1985-12-05 1990-07-11 Baxter International Inc. Apparatus for controlling rotational speed by optical data collection
EP0377481A3 (en) * 1985-12-05 1992-01-15 Baxter International Inc. Apparatus for controlling rotational speed by optical data collection

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